High Strength and Ductility of a MgAg/MgGdYAg/MgAg Sandwiched Plate Produced by High-Pressure Torsion

doi:10.1007/s40195-022-01510-7

Abstract

Abstract:

Due to their unique precipitation behavior, magnesium-rare earth (Mg-RE) alloys exhibit excellent strength and high thermal stability. However, owing to the negative blocking effect of precipitation on dislocation slipping, the plasticity and ductility of Mg-RE alloys become deteriorate after aging treatment. In this work, a novel strategy to improve the combination of strength and ductility by designing a laminate heterostructured Mg alloy is proposed. High-pressure torsion (HPT) processing is employed to fabricate a clean and well-bonded interface between MgGdYAg and MgAg alloys. The two alloys have huge differences in precipitation hardening, and ductility is improved due to two facts. For one thing, the density of the second phases in the MgAg alloy is much lower than that of MgGdYAg alloy; for another, the non-basal 〈c + a〉 slipping is continuously activated during deformation. Through this mechanism, the uniform elongation of the heterostructured MgAg/MgGdYAg/MgAg alloy is improved to 7.1%.

Key words: Heterogeneous, Mechanical properties, Mg-RE alloys, Laminate

Qile Huo, Yaxin Chen, Bo Gao, Yi Liu, Manping Liu, Xuefei Chen, Hao Zhou. High Strength and Ductility of a MgAg/MgGdYAg/MgAg Sandwiched Plate Produced by High-Pressure Torsion[J]. Acta Metallurgica Sinica (English Letters), 2023, 36(2): 343-351.

Figures/Tables 10

Table 1 Initial thickness and structures of three groups of HPT samples

Sandwich	Homogeneous MgAg	Homogenous MgGdYAg
MgAg 0.8 mm	3.2 mm	3.2 mm
MgGdYAg 1.6 mm
MgAg 0.8 mm

Fig. 1 Microstructures of the interface between MgGdYAg and MgAg produced by HPT: a SEM image, b close-up view of the yellow box in a, c bright-field TEM image, d high-resolution TEM image

Fig. 2 Chemical composition distribution near the interface of sandwich sample after HPT: a HAADF-TEM image, b-f EDS mappings in the region of white box in a

Fig. 3 Aging-hardening curves of MgGdYAg and MgAg samples treated at 200 °C

Fig. 4 Microstructures of MgAg layer of HPT sandwich after aging: a low-magnified bright-field TEM image, b high-magnified bright-field TEM image, c selected area diffraction pattern

Fig. 5 Microstructures of MgGdYAg layer of HPT sandwich after aging: a bright-field TEM image of γ″ phase view with g = 0002, b selected area diffraction pattern of γ″ phase, c corresponding simulated diffraction pattern of γ″ phase, d bright-field TEM image of β′ phase view with g=$\overline{1}010$, e selected area diffraction pattern of β′ phase, f corresponding simulated diffraction pattern of β′ phase

Fig. 6 HAADF-STEM images of the precipitations γ″ phase and β′ phase in MgGdYAg layer: a and b microstructures of γ″ phase viewed along [$1\overline{2}10$]Mg and [0001]Mg zone axes, respectively, c close-up image of γ″ phase viewed along [0001]Mg zone axis, d and e microstructures of β′ phase viewed along [$1\overline{2}10$]Mg and [0001]Mg zone axes, respectively, f close-up image of β′ phase viewed along [0001]Mg zone axis

Fig. 7 Mechanical properties of HPT sandwich, MgGdYAg and MgAg after aging: a uniaxial tensile engineering stress-strain curves, b true stress-strain curves, c strain-hardening (Θ) curves from tensile tests

Fig. 8 Schematic diagrams illustrating the evolution of microstructure of HPT heterostructure sandwich: a microstructure of interface area after deformation, b HDI stress in the interface

Fig. 9 Microstructures of HPT sandwich after tensile deformation: a bright-field TEM image and selected area diffraction pattern of MgAg, b, c high-magnified TEM images of MgAg viewed with g = $\stackrel{\mathrm{-}}{1}010$ and g = 0002, respectively, d bright-field TEM image and selected area diffraction pattern of MgGdYAg, e, f high-magnified TEM images of MgGdYAg viewed with g = $\stackrel{\mathrm{-}}{1}010$ and g = 0002, respectively

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